MPO-ANCA GN is a major cause of renal failure. Current treatments are toxic and poorly effective. Excessive DNA production resulting in prominent deposits of extracellular DNA are seen in glomeruli of patients with MPO-ANCA GN. This study will look at the pathological role of DNA and in a relevant animal model, use DNase I treatment to dissolve deposited DNA and treat anti-MPO autoimmunity and GN. This evidence will allow the introduction of DNase I in clinical trials.
Development Of A Simple Chemical Test For Detecting DNA-interacting Compounds For Medical And
Funder
National Health and Medical Research Council
Funding Amount
$315,450.00
Summary
The project exploits a simple chemical reaction to detect and measure the interaction of compounds with DNA. The test will be useful in the early screening of drug candidates for genotoxicity, identifying new anticancer drugs and also find application in the environmental, cosmetic and food industries. Work will focus on establishing peak conditions for the test, determining the scope of application, testing a panel of control compounds and performing a blind study to provide proof of concept.
Development Of DNA Targeted Platinum Agents As Potential Anticancer Drugs
Funder
National Health and Medical Research Council
Funding Amount
$410,250.00
Summary
A number of clinically useful anticancer drugs damage DNA. As a result of this damage these drugs kill cancer cells. This project aims to develop new platinum-containing compounds which are specifically targeted to DNA. Through this strategy it is possible that new and more useful anticancer drugs could emerge.
Rational Design And Development Of New Anthracenedione Derivatives
Funder
National Health and Medical Research Council
Funding Amount
$471,702.00
Summary
Our laboratory has discovered a way to activate the anti-cancer drug mitoxantrone to make it bind to DNA more effectively. This involves pre-activating it with the simple molecule formaldehyde. This concept has enabled us to design new anticancer drugs that are predicted to be more effective at killing cancer cells. In this study we will synthesise these new compounds then test how effectively they bind to DNA, inhibit growth of tumour cells in culture, and inhibit growth of tumours in mice.
Defining The Genomic And Therapeutic Landscape Of Familial Breast Cancer
Funder
National Health and Medical Research Council
Funding Amount
$1,146,096.00
Summary
As a cancer develops it accumulates alterations (mutations) in its DNA. Some of these alterations lead to enhanced tumour growth, whilst others provide insight into normal processes that have gone wrong to enable the tumour to arise. We will use DNA sequencing and mathematical approaches to characterise these alterations and to identify therapeutic targets in breast tumours arising in patients with an inherited predisposition to develop cancer.
FANC Gene Mutations In Acute Myeloid Leukaemia Biology And Treatment
Funder
National Health and Medical Research Council
Funding Amount
$900,780.00
Summary
We have found mutations in DNA repair genes in AML patients, and associated the presence of these with increased risk of developing AML. Our hypothesis is that the presence of these mutations leads to reduced efficiency of DNA repair, and increased risk of additional mutations and leukaemic transformation. Our aim is therefore to determine the changes associated with these mutations in blood cell precursors, and to investigate the potential of targeted therapies for this group of patients.
DNA Lesions Involved In Chemotherapy Responses And Their Repair
Funder
National Health and Medical Research Council
Funding Amount
$399,142.00
Summary
The integrity of the human genome is constantly threatened by spontaneous DNA damage from products of normal metabolism, for example DNA oxidation, or environmental mutagens and carcinogens such as UV light. Improperly repaired DNA damage is a major contributing factor to the onset of cancer. To prevent this, human cells have a multitude of specialised DNA repair mechanisms to repair distinct lesions in the best possible way. As a consequence, mutations in DNA repair genes lead to increased canc ....The integrity of the human genome is constantly threatened by spontaneous DNA damage from products of normal metabolism, for example DNA oxidation, or environmental mutagens and carcinogens such as UV light. Improperly repaired DNA damage is a major contributing factor to the onset of cancer. To prevent this, human cells have a multitude of specialised DNA repair mechanisms to repair distinct lesions in the best possible way. As a consequence, mutations in DNA repair genes lead to increased cancer risk. Common examples for cancer-associated DNA repair gene mutations include the BRCA1 and BRCA2 breast cancer genes, and the MLH1 gene mutated in familial non-polyposis colorectal cancer. We have identified a novel human DNA repair protein termed ASCIZ that performs a function similar to BRCA1 and BRCA2 in that it regulates the concentration of the RAD51 repair protein in specific DNA repair centres in the cell nucleus. However, compared to BRCA1-BRCA2, ASCIZ performs this function in response to different types of DNA damage and acts in concert with the MLH1 protein. Here we want to investigate what the specific DNA lesions are that are repaired by ASCIZ, and we want to determine if the repair involves a copy mechanism that utilises intact genes as repair templates. In addition, we want to generate animals in which the ASCIZ gene is mutated, as a model to study its role in cancer development in humans. Cells that lack ASCIZ are dramatically hypersensitive to DNA damaging agents that are similar to clinically used chemotherapy drugs. We hope that our studies may identify possible approaches to develop drugs against ASCIZ and related proteins in order to kill cancer cells more efficiently.Read moreRead less
Synthetic Lethality Screen Targeting A Defective Checkpoint In Melanoma
Funder
National Health and Medical Research Council
Funding Amount
$552,121.00
Summary
All cancers have defects in the mechanisms that regulate normal cell growth and division. These defects provide a growth advantage for the cancer, but can also be an Achilles Heel. In this project we will investigate targeting a defective control mechanism we found in a high proportion of melanomas. We will identify genes that when inhibited combine with the defective control to specifically kill tumour cells with this defect. Normal tissue is protected by its intact regulatory mechanism.
Regulation And Assembly Of Nuclear DNA Repair Centres
Funder
National Health and Medical Research Council
Funding Amount
$457,267.00
Summary
Genetic defects in DNA repair genes are associated with increased cancer risk in humans. For example, BRCA1 and BRCA2 gene mutations are the most common causes of familial breast cancer, and MLH1 gene mutations are the most common cause of familial non-polyposis colorectal cancer. We have identified a novel human DNA repair protein termed ASCIZ that performs a similar function to BRCA1 and BRCA2 in that it regulates the concentration of the RAD51 repair protein in specific DNA repair centres in ....Genetic defects in DNA repair genes are associated with increased cancer risk in humans. For example, BRCA1 and BRCA2 gene mutations are the most common causes of familial breast cancer, and MLH1 gene mutations are the most common cause of familial non-polyposis colorectal cancer. We have identified a novel human DNA repair protein termed ASCIZ that performs a similar function to BRCA1 and BRCA2 in that it regulates the concentration of the RAD51 repair protein in specific DNA repair centres in the cell nucleus. However, ASCIZ performs this function in response to different types of DNA damage than BRCA1-BRCA2, and it acts in concert with the MLH1 protein. Here we want to study how ASCIZ regulates the assembly of DNA repair centres, and if it does so with support by the BRCA1-BRCA2 proteins. We also want to know if DNA repair functions of the RAD51 protein are diminished when it is not located in repair centres, and we want to identify novel proteins involved in this process. Our preliminary data show that cells that lack ASCIZ become dramatically hypersensitive to DNA damaging agents that are similar to clinically used chemotherapy drugs. We hope that our studies may identify possible approaches to develop drugs against ASCIZ and related proteins in order to kill cancer cells more effectively.Read moreRead less